The ability of TRIM3 to induce growth arrest depends on RING-dependent E3 ligase activity.

Mutation of the TRIM (tripartite motif)-NHL family members brat and mei-P26 perturb the differentiation of transit-amplifying progenitor cells resulting in tumour-like phenotypes. The NHL (named after the NCL1, HT2A and LIN41 repeat) domain is essential for their growth suppressive activity, and they can induce cell-cycle exit in a RING-independent manner. TRIM3 is the only bona fide tumour suppressor in the mammalian TRIM-NHL subfamily and similar to the other members of this family, its ability to inhibit cell proliferation depends on the NHL domain. However, whether the RING domain was required for TRIM3-dependent cell-cycle exit had not been investigated. In the present study, we establish that the RING domain is required for TRIM3-induced growth suppression. Furthermore, we show that this domain is necessary to promote ubiquitination of p21 in a reconstituted in vitro system where UbcH5a is the preferred E2. Thus the ability of TRIM3 to suppress growth is associated with its ability to ubiquitinate proteins.

Tyrosine phosphorylation of the p21 cyclin-dependent kinase inhibitor facilitates the development of proneural glioma.

Phosphorylation of Tyr-88/Tyr-89 in the 3(10) helix of p27 reduces its cyclin-dependent kinase (CDK) inhibitory activity. This modification does not affect the interaction of p27 with cyclin-CDK complexes but does interfere with van der Waals and hydrogen bond contacts between p27 and amino acids in the catalytic cleft of the CDK. Thus, it had been suggested that phosphorylation of this site could switch the tumor-suppressive CDK inhibitory activity to an oncogenic activity. Here, we examined this hypothesis in the RCAS-PDGF-HA/nestin-TvA proneural glioma mouse model, in which p21 facilitates accumulation of nuclear cyclin D1-CDK4 and promotes tumor development. In these tumor cells, approximately one-third of the p21 is phosphorylated at Tyr-76 in the 3(10) helix. Mutation of this residue to glutamate reduced inhibitory activity in vitro. Mutation of this residue to phenylalanine reduced the tumor-promoting activity of p21 in the animal model, whereas glutamate or alanine substitution allowed tumor formation. Consequently, we conclude that tyrosine phosphorylation contributes to the conversion of CDK inhibitors from tumor-suppressive roles to oncogenic roles.

p27kip1 protein levels reflect a nexus of oncogenic signaling during cell transformation.

SV40 small t-antigen (ST) collaborates with SV40 large T-antigen (LT) and activated rasv12 to promote transformation in a variety of immortalized human cells. A number of oncogenes or the disruption of the general serine-threonine phosphatase protein phosphatase 2A (PP2A) can replace ST in this paradigm. However, the relationship between these oncogenes and PP2A activity is not clear. To address this, we queried the connectivity of these molecules in silico. We found that p27 was connected to each of those oncogenes that could substitute for ST. We further determined that p27 loss can substitute for the expression of ST during transformation of both rodent and human cells. Conversely, knock-in cells expressing the degradation-resistant S10A and T187A mutants of p27 were resistant to the transforming activities of ST. This suggests that p27 is an important target of the tumor-suppressive effects of PP2A and likely an important target of the multitude of cellular oncoproteins that emulate the transforming function of ST.

Interweaving the cell cycle machinery with cell differentiation.

A comprehensive understanding of the mechanisms coupling cell cycle exit and differentiation is important for both cancer biology and tissue development. Cancer cells can arise from either stem/progenitor cells that fail to exit the cell cycle and differentiate, or from de-differentiated cells that have re-entered the cell cycle. Much of our current understanding of this coupling is based on observations made in transformed cell lines. These studies have shown that enforcing proliferation prevents differentiation and inducing growth arrest leads to differentiation; thus, one widely-held view is that changes in cell cycle regulators simply induces cell cycle exit, a pre-requisite for differentiation. However, recent evidence indicates that cell cycle regulators can affect differentiation in other ways as well. They can have a role establishing the new transcriptional program that accompanies differentiation--in its most radical form, the molecular mechanism of arrest might even be an integral component of the differentiation program. Additionally, the regulators or mechanisms that prevent the re-entry of cells into the proliferative cycle may not be those that induce exit from the cell cycle. Our goal in this perspective is to highlight examples from our laboratory that provided a broader understanding of the types of roles that cell cycle regulators play during differentiation, beginning with the phenotypes observed in mice.

Somatic cell type specific gene transfer reveals a tumor-promoting function for p21(Waf1/Cip1).

How proteins participate in tumorigenesis can be obscured by their multifunctional nature. For example, depending on the cellular context, the cdk inhibitors can affect cell proliferation, cell motility, apoptosis, receptor tyrosine kinase signaling, and transcription. Thus, to determine how a protein contributes to tumorigenesis, we need to evaluate which functions are required in the developing tumor. Here we demonstrate that the RCAS/TvA system, originally developed to introduce oncogenes into somatic cells of mice, can be adapted to allow us to define the contribution that different functional domains make to tumor development. Studying the development of growth-factor-induced oligodendroglioma, we identified a critical role for the Cy elements in p21, and we showed that cyclin D1T286A, which accumulates in the nucleus of p21-deficient cells and binds to cdk4, could bypass the requirement for p21 during tumor development. These genetic results suggest that p21 acts through the cyclin D1-cdk4 complex to support tumor growth, and establish the utility of using a somatic cell modeling system for defining the contribution proteins make to tumor development.

p27kip1 Regulates cdk2 activity in the proliferating zone of the mouse intestinal epithelium: potential role in neoplasia.

BACKGROUND & AIMS: Reduced p27(kip1) expression is a marker of poor prognosis in colorectal neoplasia, and inactivation of p27 in mice (p27(Delta51/Delta51)) causes increased intestinal epithelial cell proliferation and small and large intestinal neoplasia in a diet-dependent manner. Here, we addressed the role of p27 in untransformed intestinal epithelial cells in vivo and the consequence of its targeted inactivation. METHODS: A sequential fractionation procedure was used to isolate murine intestinal epithelial cells relative to their position along the crypt-villus axis, and the levels of cyclins, cyclin-dependent kinases (cdks), and cdk inhibitors and of the complexes formed among them was determined by immunoprecipitation-immunoblotting and kinase assays. RESULTS: As cells exited the proliferative crypt compartment, expression and activity of both cdk2 and cdk4 decreased, in parallel with reduced expression of cyclin A and proliferating cell nuclear antigen (PCNA); expression of cyclin D1, D2, and cyclin E showed little change. As expected, expression of the cdk inhibitors p21, p57, and p16 was highest in differentiated villus cells. Unexpectedly, p27 protein expression was highest in cells of the proliferative crypt compartment where it bound both cdk2 and cdk4. Cdk2 activity was increased in crypt cells from p27(Delta51/Delta51) mice, although cyclin D-associated kinase activity was unchanged (indeed, cyclin D1/2-cdk4 complex levels were reduced). Importantly, cdk2 activity was unchanged in crypt cells from p21(-/-) mice, which do not develop intestinal tumors. CONCLUSIONS: We propose that p27 contributes to intestinal epithelial homeostasis by regulating cdk2 activity in proliferating cells, thus gating cell cycle progression and suppressing intestinal neoplasia.

Cooperation between p27 and p107 during endochondral ossification suggests a genetic pathway controlled by p27 and p130.

Pocket proteins and cyclin-dependent kinase (CDK) inhibitors negatively regulate cell proliferation and can promote differentiation. However, which members of these gene families, which cell type they interact in, and what they do to promote differentiation in that cell type during mouse development are largely unknown. To identify the cell types in which p107 and p27 interact, we generated compound mutant mice. These mice were null for p107 and had a deletion in p27 that prevented its binding to cyclin-CDK complexes. Although a fraction of these animals survived into adulthood and looked similar to single p27 mutant mice, a larger number of animals died at birth or within a few weeks thereafter. These animals displayed defects in chondrocyte maturation and endochondral bone formation. Proliferation of chondrocytes was increased, and ectopic ossification was observed. Uncommitted mouse embryo fibroblasts could be induced into the chondrocytic lineage ex vivo, but these cells failed to mature normally. These results demonstrate that p27 carries out overlapping functions with p107 in controlling cell cycle exit during chondrocyte maturation. The phenotypic similarities between p107(-/-) p27(D51/D51) and p107(-/-) p130(-/-) mice and the cells derived from them suggest that p27 and p130 act in an analogous pathway during chondrocyte maturation.

p130Rb2 and p27kip1 cooperate to control mobilization of angiogenic progenitors from the bone marrow.

Neoangiogenesis involves both bone marrow-derived myelomonocytic and endothelial progenitor cells as well as endothelial cells coopted from surrounding vessels. Cytokines induce these cells to proliferate, migrate, and exit the cell cycle to establish the vasculature; however, which cell cycle regulators play a role in these processes is largely unknown. Here, we report that mice lacking the cell cycle inhibitors p130 and p27 show defects in tumor neoangiogenesis, both in xenografts and spontaneously arising tumors. This defect is associated with impaired mobilization of endothelial and myelomonocytic angiogenic progenitors from the bone marrow. This article documents the role of these molecules in angiogenesis and further suggests that cell expansion and mobilization from the bone marrow of angiogenic precursors are separable events.